The Photochemistry of Thiophenes. IV. Observations on the Scope of

was done in a "quantum yield merry-go-round" using light of 31 30 A. Vapor chromatographic analysis on a 12-ft fluorosilicone column was used to follo...
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3487 using three freeze-thaw cycles and sealed under a pressure of about 3 x 10-4 torr in 13 X 100 mm Pyrex culture tubes. Irradiation was done in a "quantum yield merry-go-round" using light of 31 30 A. Vapor chromatographic analysis on a 12-ft fluorosilicone column was used to follow both the disappearance of the ketone and the appearance of the dimers. The relative rates of reaction were determined and, in the case of low concentrations where under 99 of the light was absorbed by the enone, the rates were corrected for incomplete absorption before calculation of quantum yields. A correlation of the relative quantum yield with the absolute quantum yieldwas made by irradiation of a solution 1.016 M in cyclohexenone to 2 0 z conversion with cyclohexadiene actinometers. The quantum yield for the disappearance of the ketone was found to be 0.286. Product Distribution. The cyclohexenone dimers were analyzed on the 12-ft fluorosilicone column and the relative areas under the peaks were taken as the relative amounts of the dimers formed. The column temperature was 250". Quenching by Piperylene. Solutions containing the same concentration of cyclohexenone (1.024 M) but containing different concentrations of piperylene (from none to 2 M) were prepared,

degassed in the usual manner, and irradiated in the "quantum yield merry-go-round" with the 3660-A filter system until a conversion of 15 % was obtained in the sample containing no piperylene. The tubes were opened and analyzed for the appearance of dimers by vapor chromatography using the fluorosilicone column. Intersystem Crossing Efficiencies. One set of solutions containing 0.05, 0.10, 0.2, and 0.4 M cyclohexenone and 0.0526 M cis-1,2diphenylpropene and another set containing the same concentrations of cyclohexenone along with 0.0525 M trans-1 ,Zdiphenylpropene were prepared as usual and irradiated using the 3660-A filter system. Actinometric solutions containing 0.06 M benzophenone and 0.0526 M cis-1,Zdiphenylpropene or 0.0528 M truns-l,2-diphenylpropene were irradiated in parallel with the test solution. The tubes were opened and analyzed using the fluorosilicone column described above. Conversions were 6% or less. The values of + i o were calculated using the published method assuming that + i o for benzophenone is unity and that decay of diphenylpropene triplets gives 44.5 % of the trans isomer. Acknowledgment. This study was supported by a grant f r o m the National Science Foundation.

The Photochemistry of Thiophenes. IV. Observations on the Scope of Arylthiophene Rearrangements Hans W y n b e r g , H. van Driel,' R i c h a r d M. Kellogg, and J. Buter Contribution from the Department of Organic Chemistry, The University, Groningen, The Netherlands. Received February 1, 1967 Abstract: U p o n irradiation with ultraviolet light in benzene or ether solution 2-phenylthiophene rearranges smoothly a n d irreversibly to 3-phenylthiophene. T h e phenyl group remains attached t o the same carbon a t o m during rearrangement as shown by a 14C labeling experiment. A series of previously unreported arylthiophenes have been synthesized t o help establish the scope a n d mechanism of the reaction. Experiments with 2-p-tolyl- and mesitylthiophenes show that rearrangement is confined t o the thiophene ring a n d does not occur in the phenyl ring. Photolysis of 2-(a-naphthyl)thiophene leads t o 3-(a-naphthyl)thiophene a n d similarly 2-@-naphthyl)thiophene affords 3-@-naphthyl)thiophene upon photolysis. 2,3-Diphenylthiophene undergoes a cyclohexatriene-type ring closure to form the previously unreported phenanthro[9,10-b]thiophene. 3,4-Diphenylthiophene rearranges t o 2,3-diphenylthiophene (isolated a s phenanthro[9,10-b]thiophene)plus a small amount of 2,4-diphenylthiophene. Photolysis of 2,4-diphenylthiophene gives 3,4-diphenylthiophene a s t h e primary photolysis product. 2,5-Diphenylthiophene is virtually unreactive even upon extended photolysis.

he T reaction have

photoinduced rearrangement of 2-phenyl- to 3-phenylthiophene (eq 1) and variations of this been briefly described by us. 2--6 Attempts have been made to investigate both the scope and mechanism of this rearrangement and to correlate some o f our findings with new results in the rapidly g r o w i n g field of photolysis o f aromatic systems. The possible connection between this p h o t o r e a r r a n g e m e n t and those reported i n some benzenoid systems was pointed out earlier, 2 * a and investigations on this reaction have been designed to shed some light on this hypothesis. This paper reports studies of the r e a c t i o n scope from which certain mechanistic conclusions can be drawn. F o l l o w i n g papers6.' report labeling experi-

(1) Royal Dutch Shell Fellow, 1963-1966. (2) H. Wynberg and H. van Driel, J. Am. Chem. Soc., 87, 3998 (1965). (3) H.Wynberg and H. van Driel, Chem. Commun., 204 (1966). (4) H.Wynberg and R. M. Kellogg, 152nd National Meeting of the American Chemical Society, New York, N. Y., Sept 1966. ( 5 ) H. Wynberg, R. M. Kellogg, H. van Driel, and G. E. Beekhuis, J . Am. Chem. Soc., 88, 5047 (1966). (6) R. M. Kellogg and H . Wynberg, ibid., 89, 3495 (1967). (7) H.Wynberg, G.E. Beekhuis, H. van Driel, and R. M. Kellogg, ibid., 89, 3498 (1967).

ments carried out to e l u c i d a t e the mechanism in more detail and conclusions are contained in the last paper o f t h i s series.8

1

2

Results Irradiation o f 2 - p h e n y l t h i o p h e n e in dilute ether solution leads to 3-phenylthiophene as the exclusive r e a r r a n g e m e n t p r o d u c t (eq I). No rearrangement occurs in the absence o f u l t r a v i o l e t i r r a d i a t i o n . Careful gas c h r o m a t o g r a p h i c analysis o f reaction mixtures failed to give any evidence o f the presence of other products even i n trace amounts. S o l u t i o n s became light yellow on extended i r r a d i a t i o n and a solid, intractable p r e c i p i t a t e f o r m e d on the lamp. The p r o g r e s s o f the r e a c t i o n with time is shown in Figure 1. The (8) H. Wynberg, R. M. Kellogg, H. van Driel, and G. E. Beekhuis, ibid., 89, 3501 (1967).

Wynberg, van Driel, Kellogg, Buter

Arylthiophene Rearrangements

3488

authentic material. Photolysis of 6 alone led to no new products. l o The synthesis and irradiation of 2,5-l4C-2-pheny1thiophene (7) has been briefly d e ~ c r i b e d . ~This compound was prepared from 1,4-14C-labeled succinic acid by a modification of the method of Chrzaszczewska.I1 Photolysis of 7 was carried out in ca. l e 3 M ether solution, and the active 3-phenylthiophene (S), which was recovered, was oxidized12 to benzoic acid which was counted13 (eq 4). Within experimental

0.6

a3

8

I

Time (min)

Figure 1. Rate of disappearance of 6 X M ether solution of 2-phenylthiophene, 0; rate of formation of 3-phenylthiophene from 6 X M 2-phenylthiophene, A ; and rate of disappearance of a 6 X 10-3 M solution of 3-phenylthiophene in ether, 0 .

I 0.0310 2 0,0003

reaction tends toward a steady-state concentration after a few hours irradiation (roughly 6 hr). During the first 120 min it may be seen that 40-50x of the 2phenylthiophene that has disappeared is found as 3phenylthi~phene.~Qualitative experiments at ca. -40 and 20" in ether solution indicated no appreciable rate change in the rearrangement. The rate of disappearance of 2-phenylthiophene increases in more polar solvents (see Experimental Section). Photolysis of 3-phenylthiophene in solution leads only to decomposition; the rate of decomposition of 3phenylthiophene is shown also in Figure 1. Gas chromatography under conditions capable of detecting 2phenylthiophene in amounts as small as 0 . 2 5 z of the remaining 3-phenylthiophene failed to detect any of this isomer or any other products. Photolysis of 2-(ptolyl)thiophene (3) gave only 34ptoly1)thiophene (4) (eq 2) identified by comparison of

m curies/mole

error the activity of recovered benzoic acid (rigorously purified) was the same from the 2- and 3-phenylthiophenes. The particular method of degradation accounts only for the 14C originally in the 2 position of starting material 7. The results establish that the phenyl group remains attached to the same carbon atom during rearrangement. The four isomeric naphthylthiophenes were synthesized to provide systems with a different aryl substituent. 2-(a-Naphthyl)thiophene (9) and 2-(P-naphthy1)thiophene (10) were synthesized from the 3-naphthoylpropionic acids. 3-(a-Naphthyl)thiophene (11) and 3-(fl-naphthyl)thiophene (12) were prepared by the general method of Wynberg, Logothetis, and VerPloeg.14 Photolysis of 9 in dilute ether solution gave 11 as the only product (eq 5). The identification of 11

4

infrared, nmr, and ultraviolet spectra and gas chromatographic retention times with those of authentic material synthesized by an unambiguous route (see Experimental Section). As a further check 3-(rn-tolyl)- and 3-(o-tolyl)thiophene were prepared and were shown to have characteristics different from those of 4. Photolysis of 4 alone led only to decomposition. 2-Mesitylthiophene (5) was prepared and photolyzed (eq 3). The rearrangement product was shown to be 3-mesitylthiophene (6) identical in all respects with

0.0318 i0.0007 m curiesj'mole

11

was accomplished by comparison of gas chromatographic retention times, infrared spectra, and ultraviolet spectra with those of known compounds. Photolysis of 10 in dilute ether solution gave only 12 as product (eq 6). Within limits of gas chromatographic detec-

10

12

(10) The rate of rearrangement (and decomposition) qualitatively appears to increase with increasing alkyl substitution, Le., the order of rates is 5 > 3 > 1. The rate diffcrcnce may be due to differences in ultraviolet absorption intensities caused by alkyl substitution. (11) A. Chrzaszczewska, Roczniki Chem., 5, 1 (1925); Chem. Absrr.,

5

6

(9) Photolysis in benzene in the presence of NazSzOs.6HzO appears to give considerably higher yields of 3-phenylthiophene. We cannot currently explain this observation. Some diphenyl is produced in this reaction, apparently originating from the benzene.

Journal of the American Chemical Society / 89:14 / July 5, 1967

20, 1078 (1926). (12) General method of H. Wynberg and A. P. Wolf, J . A m . Chem. Soc., 85, 3308 (1963), used for the oxidation of biphenyls.

(13) We thank Professor Dr. M. Gruber, Department of Biochemistry of this university, for providing facilities and Dr. J. U. Vecnland for performing the radioactivity measurements in the laboratory of Professor Dr. Th. J. de Boer of the University of Amsterdam. (14) H. Wynbcrg, A. Logothetis, and D. VerPloeg, J . Am. Chem. Soc., 79, 1972 (1957).

3489

tion no a to /3 or /3 to a rearrangements occurred in the naphthalene ring. Photolysis of 11 or 12 in dilute ether solution led only to very slow decomposition. No new products were formed in detectable amounts.

phenylfuran upon ph~tolysis"~ and the formation of triphenylene from o-terphenyl. Apparently in this case a ring closure is preferred to any possible rearrangement reaction (with the exception of the interchange of the 2,3-carbon atoms which cannot be detected). Photolysis of 3,4-diphenylthiophene (eq 9) in dilute ether solution gave a major product identified as phenanthrol[9,10-b]thiophene (14). The product was shown

14

Further information on the scope and mechanism of the reaction was obtained from photolysis of the isomers of diphenylthiophene. Irradiation of 2,3-diphenylthiophene (13) in dilute ether solution gave a single product (eq 7) isolated in high yield which was identified as phenanthro[9,lO-b]thiophene (14) from physical and chemical data (see Experimental Section). For unambiguous structure proof, previously unreported 14 was prepared by direct synthesis as shown in eq 8. The intermediate products in the synthesis were carefully characterized and analyzed because of inadequate descriptions in the literature. l5 Subsequent

CICH>CO,Hb

~ s c H z c o ~ H 2.AlCI.7 I.SOC12

-

15

minor major

16

14

definitely not to be phenanthro[9,10-~]thiophene(17).

.

~

@sH / \

17

\

go ;i%" A

/%

Zn-HOAc+

/

14

CrOa,

0 (8)

/

investigations have shown that 14 can be synthesized in one step in 17x yield by the photolysis of 2,3-diiodothiophene in benzene. l 6 The reaction of 2,3-diphenylthiophene represents another example of the extensively studied stilbenetype ring closures to yield phenanthrene derivatives.17a-c Dissolved oxygen in the system serves as the oxidant. A direct analogy of this reaction is the recently reported formation of phenanthro[9,104]furan from 2,3-di(15) (a) R. Wilputte and R. H. Martin, Bull. SOC.Chim. Belges, 65, 874 (1956); (b) P. C. Dutta, J. Indian Chem. SOC.,18, 469 (1941). (16) These results were obtained in conjunction with an extensive investigation of the photolysis of mono- and diiodothiophenes in various aromatic solvents (benzene, mesitylene, naphthalene, thiophene). This technique has been shown to be a convenient preparative method for a number of arylthiophenes. Correlations have also been carried out on the relative rates of arylation of the 2 and 3 positions of thiophene. A brief description of the photolysis technique can be found in paper V of this series. The photolysis of 2,3-diiodothiophene and 2,3diiodothianaphthene has also been examined with a view toward the photochemical generation of thiophynes. The use of iodoaromatics in photoarylations has been extensively described: W. Wolf and N. Kharasch, J. Org. Chem., 30, 2493 (1965), and references contained therein. While this work was in progress a description of the photolysis of 2- and 3-phenylthiophene in benzene and substituted benzenes appeared confirming some of our results: L. Benati and M. Tiecco, Boll. Sci. Fac. Chim. Ind. Bologna, 24, 45 (1966); Chem. Abstr., 65, 8710f(1966). The work done in our laboratories will soon be published. (17) (a) F. B. Mallory, C. S. Wood, and J. T. Gordon, J . Am. Chem. Soc., 86, 3094 (1964). (b) J. Cornelisse, Thesis, Leiden University, 1964. (c) Similar ring closure reactions have been observed in this laboratory with dithienylethylenes and difurylethylenes: R.M. Kellogg, M. B. Groen, and H. Wynberg, paper in preparation. (d) A. Padwa and R. Hartman, J. Am. Chem. Soc., 88, 3759 (1966). These authors further report that they failed to observe rearrangements with the other diphenylfuran isomers. (e) N. Kharasch, T. G. Alston, H. B. Lewis, and W. Wolf, Chem. Commun., 242 (1965).

In addition to 14, a second product (ca. 8 the amount of 14) was formed during photolysis. This material had the same retention time as 2,4-diphenylthiophene (16) and a sample trapped from the gas chromatograph exit port had the same ultraviolet spectrum as authentic 16. The structure was further confirmed by the identification of 1,3-diphenylbutane upon desulfurization of a reaction mixture with Raney nickel. The 3,4-diphenylthiophene most likely rearranges first to 2,3-diphenylthiophene and 2,4-diphenylthiophene. The 2,3-diphenylthiophene then undergoes rapid ring closure to form the phenanthro derivative. The failure of 3,4-diphenylthiophene to form 17 by direct photochemical ring closure may be associated with the lack of sufficient "double-bond" character between the 3,4-carbons of the thiophene ring or rearrangement may represent a more favorable path in this case. l9 Photolysis of 2,6diphenylthiophene (16) in dilute ether solution led first to the formation of 3,4-diphenylthiophene (15) as identified by infrared spectra and gas

16 L

1s

14

(18) We thank Dr. S. van der Werf of this laboratory for providing us with authentic 17. (19) Interestingly, on tetraphenylthiophene photolysis in dilute ether solution for over 100 hr failed to show any detectable change except for a lowering of the ultraviolet extinction. No-reaction reactions involving carbon-carbon interchange could not, of course, be detected.

Wynberg, van Driel, Kellogg, Buter

Arylthiophene Rearrangements

3490

chromatographic retention time. Further irradiation gave phenanthrene 14 as a secondary photolysis product (eq IO). 2,5-Diphenylthiophene (17) upon photolysis for extendedperiods gave no major photolysis products. Two very small peaks with the same retention times as 15 and 14 were seen in the gas chromatogram. Examination of the ultraviolet spectrum of irradiated material showed small, sharp peaks at 254 and 260 mp highly characteristic of 14 (see Experimental Section). Discussion The photochemical rearrangement of 2-aryl-substituted thiophenes occurs with a number of different aryl substituents, thus phenyl, p-tolyl, mesityl, and naphthyl all are rearranged to the 3 position. These rearrangements must occur by some mechanism involving extensive rebonding in the thiophene ring; the results of I4Clabeling require this conclusion. The rearrangements of the diphenylthiophenes are more involved than those of monoarylthiophenes. The most remarkable result obtained is perhaps the specificity of rearrangement leading to one primary product in all cases. This suggests a general path for the rearrangement which could be elucidated if one knew the location of all the carbon atoms in the thiophene ring after rearrangement. Experiments designed to answer this question are described in the next two papers and mechanistic conclusions are presented in the last paper of this series. Experimental Section All melting points are corrected; boiling points are uncorrected. Merck Grade aluminum oxide was used for column chromatography. Ultraviolet spectra were taken on a Zeiss PMQ 11 spectrophotometer, and reactions were followed with a Cary Model 15 scanning spectrophotometer; wavelengths are reported in millimicrons with the corresponding extinction coefficients (e). Infrared spectra were taken on a Perkin-Elmer Model 125 infrared spectrophotometer. Nuclear magnetic resonance (nmr) spectra were taken with a Varian A-60 instrument with tetramethylsilane (TMS) as internal reference. Phosphorescence and fluorescence spectra were measured with the instrumem previously described2 or with an Aminco-Bowman spectrophotofluorometer and spectra photographed from the oscilloscope trace. Spectra were taken in EPA glass at liquid nitrogen temperature. Analytical gas chromatography (glpc) was carried out with an F & M Model 810 gas chromatograph equipped with hydrogen flame detectors and occasionally with a Perkin-Elmer fractometer with hydrogen flame detectors and a 165-ft butane diolsuccinate (BDS) capillary column. Preparative separations were performed with a Wilkens A-700 Autoprep. Specially designed high-efficiency trapping tubes were attached directly to the exit port of the chromatography. Many of the ultraviolet, infrared, and nmr spectra were taken by Miss K. S. Meijer and Miss H. de Groot. Microanalyses were carried out by the analytical section of this university under the direction of Mr. W. Hazenberg. Large-scale photolyses were done with a Hanau 4-700 lamp enclosed in a quartz jacket and cooled with recirculated twice-distilled water. The lamp was immersed in a cylindrical reaction vessel capable of holding approximately 550 ml of solution. Stirring was provided by a large Teflon paddle magnetically coupled with a stirrer set at the bottom of the vessel. Facilities were provided for running reactions under a nitrogen atmosphere and for removing samples as desired. Smaller scale photolyses (100-125 ml) were carried out with Hanau S-81 high-pressure mercury lamps mounted in quartz jackets. A cooling system was used consisting of twice-distilled water (or filter solution if desired) which was continually repumped through the lamp. Facilities were built into the circulating line t o allow + l o temperature control from 20 to 80". Reactions were run under constant nitrogen pressure and samples could be withdrawn as desired. The high-pressure mer-

Journal oj' the American Chemical Society

1 89:14 1 July 5, 1967

cury lamp could be readily exchanged for a Hanau NK 6-20 lowpressure lamp (2537 A). 2-Phenylthiophene (1) was usually obtained by heating the sodium salt of 3-benzoylpropionic acid (obtained by acylation of benzene with succinic anhydride) with P4S7 in the described mannerm with yields of 10-15%,21mp 34.5-35" ( M z omp 35.9-36.1'). The material was 99-100z pure as determined by glpc on a 4-ft diethylene glycol succinate (DEGS) column at 190"; ultraviolet spectrum in cyclohexane: Amax 282 (13,400) and, , ,A 222 (7500); in 96% ethanol: A, 283 (18,300) and Ash 225 (7800). The compound showed weak phosphorescence at 540 f 5 mp. 3-Phenylthiophene (2) was prepared by reaction of phenyl Grignard reagent (0.5 mole) with 3-ketotetrahydrothiophene14(50 g, 0.5 mole). The reaction mixture was acidified with 2 N HCl and extracted with ether; the ether layer was neutralized with KHCOa and dried over MgSO4. Removal of the ether left 64.5 g of oily carbinol. This oil was heated slowly with KHS04 (10 g) and S (18 g) (a considerable excess of KHSO4 and S arc necessary for good reaction) to 225' until water and H S ceased to be evolved. The remaining material was steam distilled to give 3-phenylthiophene (35.2 g, 0.22 mole, 44% yield), gas chromatographically pure; mp 89-91', after recrystallization from methanol (lit.2z 91-92"); 227 (15,300) and A,, ultraviolet spectrum in cyclohexane: , , ,A 227 (12,800) and A,, 259 259 (13,700); in 96% ethanol: , , ,A (12,000). The compound showed a strong phosphorescence at 490 & 5 mp. 2-(pTolyl)thiophene (3) was prepared from 4-(ptolyl)-4-ketobutyric acid synthesized according to the general method of de Barry-Barnett and Sanders. 2 3 A suspension of succinic anhydride (80 g, 0.8 mole) and toluene (81 g, 0.88 mole) was refluxed in tetrachloroethane (300 ml) until homogeneous. Anhydrous aluminum chloride (240 g, 1.80 moles) was added, and the reaction mixture was refluxed for 1.5 hr and stirred overnight at room temperature. The reaction mixture was poured into 10% HC1 solution and the crude precipitate was purified by repeated extractions with aqueous KOH followed by precipitation with HCI solution. Neutralization gave the sodium salt of 4-(p-tolyl)-4-ketobutyric acid (130 g, 0.61 mole, 76% yield). A sample of the free acid recrystallized from hot water had mp 145.5-146" (lit. 120" 2 4 and 127" 9.The nmr spectrum completely supported the structure of the acid. The dry sodium salt of the acid (31 g, 0.15 mole) and P4S7 (44 g, 0.13 mole) were heated in a flask equipped with a cooler and a trap for escaping gas. The flask was heated at 150" for 0.5 hr followed by a slow increase to 180" until vigorous reaction ceased followed by further heating to 250" for 0.75 hr. After cooling, water was carefully added until the reaction stopped; concentrated NaOH solution was added and the solution slowly steam distilled. The steam distillate was extracted with ether which was dried and removed. The product was decolorized twice with Norit in methanol, chromatographed over A1203 (methanol eluent), and concentrated to yield, after standing, 2-(p-tolyl)thiophene (3.2 g, 0.018 mole, 12.7% yield), mp 63-64' (lit.11 63-64'); ultraviolet spectrum in 96% ethanol: A,, 285 (15,500) and ASil 224 (6400). 3-(pTolyl)thiophene (4) was prepared according to the general method of Broun and Voronkov. * 6 p-Methylacetophenone (24 g, 0.18 mole) was allowed to react with excess ethyl Grignard reagent. The crude carbinol obtained after acidification and extraction of the reaction mixture was heated with a few crystals of iodine which effected dehydration. The 1%was removed by shaking with aqueous NaHS03. After extraction and drying the residue was distilled to give 2-(p-tolyl)butene-2, bp 87-92' (11 mm) (18 g, 0.12 mole, 59% yield), @D 1.5313; ultraviolet spectrum in 96% ethanol: A,, 246 (10,900). Anal. Calcd for CllHI4: C, 90.35; H, 9.65. Found: C, 89,7; H, 9.6. The 2-(p-tolyl)butene-2 (15 g, 0.1 mole) and S (13 g, 0.4 g-atom) were heated for 7 hr at 200". After addition of water followed by steam distillation, the product obtained was precipitated twice out of glacial acetic acid and recrystallized from 70 % methanol-water (20) J. L. Melles and H. J. Backer, Rec. Trav. Chim., 72, 314 (1953). (21) Yields as high as 30% when prepared by method of Chrzaszc-

zewska.11

(22) H. D. Hartough, "Thiophene and Its Derivatives," Interscience Publishers Inc., New York, N. Y . , 1952, p 477. (23) E. de Barry-Barnett and F. G. Sanders, J . Chem. SOC.,434(1933). (24) E. Burker, Bull. SOC.Chim. France, 49, 449 (1888). (25) H. Limprickt, Ann., 312, 110 (1900). (26) A. S. Broun and M. G. Voronkov, J . Gen. Chem. USSR, 17, 1162 (1947); Chem. Absrr., 42, 1591a (1948).

3491 t o give 3-(ptolyI)thiophene (1 g, 0.006 mole, 6% yield), mp 113113.5" (lit." 111-112'); ultraviolet spectrum in 9 6 x ethanol: ,A, 261 (14,800) and , ,A 228 (14,800). 3-(m-Toly1)thiophene was prepared by reaction of 3-ketotetrahydrothiophene (5 g, 0.95 mole) with the Grignard reagent from rn-bromotoluene (0.05 mole). After acidification and extraction with ether there remained, after removal of the ether, the carbinol (7.5 g, 7 8 S z yield), bp 116-120" (0.25 mm), n"D 1.6064. The most satisfactory method of aromatization involved heating the carbinol (3.7 g, 0.019 mole) with KHSOa (0.5 g) and S (0.8 g) very slowly t o 225 O until cessation of gas evolution. The reaction can be carried out stepwise with KHSOa followed by S but in poorer yields. The mass was taken up in water and steam distilled. The steam distillate was extracted with ether and was distilled, bp 92-96' (0.6 mm), n% 1.6200 (1.2 g, 0.0075 mole, 40% yield). The product was purified by treatment with HgCh in 96% ethanol to form the mercuric chloride salt. The yellow precipitate formed after standing at room temperature was recrystallized out of dioxane and decomposed by heating with 5 ml of 2 N HC1 solution. The organic material was extracted with benzene to give gas chromatographically pure 3-(rn-tolyl)thiophene, bp 84-86" (0.3 mm), nmD 1.6248; ultraviolet spectrum in 96% ethanol: , , ,A 260 (11,400) and hah 228 (12,700). Anal. Calcd for CIIHloS: C, 75.82; H, 5.78; S, 18.40. Found: C,76.0; H. 5.8; S, 18.1. 3-(o-Tolyl)thiophene was prepared by reaction of 3-ketotetrahydrothiophene (7.2 g, 0.07 mole) with the Grignard reagent from o-bromotoluene (0.07 mole). The carbinol obtained was treated with KHSOa (0.73 g) and S (1.16 g) as described above to give a main product (4.0 g, 0.028 mole, 33% yield), bp 85-98' (0.3 mm), n% 1.6203. The material was not pure and further purification through the mercuric chloride salt prepared as described above was necessary. After 4 weeks of standing, a precipitate was obtained which was decomposed with 2 N HC1 t o give 3-(o-tolyl)thiophene, bp 94-98' (2 mm), n% 1.6140, gas chromatographically pure; ultraviolet spectrum in 96% ethanol:, , A 247 (9100). Anal. Calcd for CI1HloS: C, 75.82; H, 5.78; S, 18.40. Found: C, 75.9; H, 5.7; S, 18.2. 2-Mesitylthiophene (5) was prepared by ring closure of 3-mesitoylpropionic acid. Succinic anhydride (20 g, 0.20 mole) and mesitylene (26.5 g, 0.22 mole) in tetrachloroethane (75 ml) were refluxed with anhydrous aluminum chloride (60 g, 0.45 mole) for ca. 1 hr. The reaction mixture was worked up by adding aqueous HCI; the tetrachloroethane was removed by steam distillation, and the remaining acid was allowed to crystallize. The acid was dissolved in aqueous NaOH, decolorized with Norit, and reprecipitated with aqueous HC1 to give 3-mesitoylpropionic acid (40 g, 0.18 mole, 90 % yield), mp 110.5-1 12 '. Anal. Calcd for C13H1603: C, 70.88; H, 7.32. Found: C, 70.9; H, 7.3. The well-dried sodium salt of the acid (30 g, 0.12 mole) was carefully heated with PIS7 (40 g, 0.115 mole) t o 180" and held at this temperature for 1 hr. Aqueous NaOH was added to the cooled mixture until all reaction stopped and the residue slowly steam distilled. The steam distillate was saturated with N H C l and extracted with CCla. After removal of the CC14 and distillation, 2mesitylthiophene was obtained, bp 101-107" (1.8 mm), nmD 1.5773 (4 g, 0.02 mole, 16 %yield), as a yellow-red oil. Upon standing the oil crystallized, and after several recrystallizations from 70% methanol-water at -40" light rose crystals of 2mesitylthiophene, mp 29.5-30.5 were obtained which were gas chromatographically pure; ultraviolet spectrum in 96 % ethanol: broad absorptions, Ash 240 (9200) and Ash 220 (13,200). Anal. Calcdfor C13HlnS: C, 77.18; H, 6.97; S, 15.85. Found: C, 77.2; H, 6.9; S, 15.6. 3-Mesitylthiophene (6) was prepared after several unsuccessful attempts by reaction of mesityl Grignard reagent with 3-ketotetrahydrothiophene. 2-Bromomesitylene27 (10 g, 0.05 mole), magnesium (1.3 g, 0.05 g-atom), and ether (25 ml) were allowed to reflux under extremely dry conditions for 16 hr. 3-Ketotetrahydrothiophene (5.0 g, 0.05 mole) in 15 ml of ether was slowly added followed by 2 lir of stirring. After work-up, the unreacted 3-ketotetrahydrothiophene and mesityl bromide were distilled under water aspirator vacuum. The residue was slowly heated with KHSO4 (0.25 g) and S (0.4 g) to 225" and held at this temperature for 1 hr. The reaction mixture was extracted with 1 :1 ethermethanol and the extract chromatographed over Alz03to give 1 g of

impure product. A pure sample (25 mg) was obtained by preparative gas chromatography (7-ft Carbowax, 170°), mp 32-34;B ultraviolet spectrum in 96 % ethanol: broad spectrum, Aah 240 (8500) and Ash 220 (17,200). Anal. CalcdforCI8HlaS: C, 77.18; H, 6.97; S, 15.85. Found: C, 76.9; H, 7.0; S, 15.7. Preparation of 3-(a-naphthoyl)- and 3-(P-naphthoyl)propionic acids was carried out by acylation of naphthalene (80 g, 0.63 mole) with succinic anhydride (40 g, 0.40 mole) in nitrobenzene (300 ml) in the presence of anhydrous aluminum chloride (110 g, 0.83 mole). After 21 hr at room temperature, dilute HC1 Has added and the nitrobenzene and excess naphthalene distilled. The remaining acid was dissolved in hot NazC03 solution, filtered, and precipitated. The acid mixture was recrystallized out of glacial acetic acid. The precipitate was mostly 3-(P-naphthoyl)propionic acid, and the 3-(a-naphthoyl)propionic acid remained in solution. Successive recrystallizati~ns~~ of the precipitate out of methanol gave 3-(P-naphthoyl)propionic acid (26 g, 0.12 mole, 28 % yield), mp 169-171' (lit.30 173-174"). Recovery of the mother liquors and successive recrystallizations out of methanol gave 3-(a-naphthoyl)propionic acid (29 g, 0.13 mole, 32% yield), mp 129-130" (1it.m 131.0-1 32.5 "). 2-(a-Naphthyl)thiophene (9) was prepared by heating the dried sodium salt of 3-(a-naphthoyl)propionic acid (22 g, 0.088 mole) with Pas, (30 g, 0.08 mole) slowly to 250" for 0.5 hr. After cooling, the mass was treated with NaOH solution and steam distilled. After extraction of the organic material followed by drying and evaporation of the solvent an oil was obtained which gave 24anaphthy1)thiophene (2.5 g, 13.5 %) upon distillation, bp 126-127' (0.25 mm), nZoD1.6905 [lit.3i bp 165" (1 mm)]; ultraviolet spectrum 296 (9700) and, , ,A 224 (42,300) in 96% ethanol: , , ,A Anal. Calcdfor C1aHIOS: C, 79.96; H, 4.79; S , 15.25. Found: C, 79.9; H,4.9; S, 15.2. 2-(P-Naphthyl)thiophene (10) was prepared by heating the dry sodium salt of 3-(~-naphthoyl)propionicacid (22 g, 0.088 mole) with Pas7(30 g, 0.086 mole) for 1.5 hr at 200". After steam distillation 2-(P-naphthyl)thiophene (2.08 g, 11 % yield) was obtained as silver gray crystals, mp 104-105' after recrystallization from 31 1 (16,200), methanol; ultraviolet spectrum in96% ethanol: ,,,A, , , ,A 273 (24,200), , , ,A 265 (25,800), and, , ,A 219 (41,200). Anal. CalcdforClaHloS: C, 79.96; H, 4.79; S, 15.25. Found: C,79.6; H,4.8; S, 14.9. 3-(a-Naphthyl)thiophene (11) was prepared by the reaction of the Grignard reagent (0.05 mole) formed from a-bromonaphthalene (Fluka A. G., Switzerland) and 3-ketotetrahydrothiophene (5.0 g, 0.05 mole). Slow addition of the bromo compound and extended refluxing were necessary to form the Grignard reagent. After hydrolysis, extraction, and distillation, the carbinol (5.6 g, 49 % yield), bp 165-175" (0.15 mm), was obtained. The carbinol (1.7 g, 0.0073 mole) was heated with KHSOa (0.25 g) and S (0.4 g) to 200' until HzS and water ceased to be evolved. The product was not steam distillable so the pyrolysis mixture was purified by chromatography over A1203 (petroleum ether-methanol-ether, 94: 3 :3). In this manner gas chromatographically (Apiezon L, 270") pure 34anaphthy1)thiophene (1.1 g, 71 % yield from the carbinol) was obtained as a viscous, colorless liquid, @D 1.6892, which failed t o crystallize on prolonged standing at - 30°;32 ultraviolet spectrum in 96% ethanol: Am,, 292 (9500) and, , ,A 224 (59,400). Anal. Calcdfor Cl4HloS: C , 79.96; H, 4.79; S, 15.25. Found: C, 79.8; H,4.9; S, 14.9.

O,

(27) L.I. Smith, Org. Syn., 11, 24(1931).

(28) A much better preparation of this compound is the photolysis of 3-iodothiophene in mesitylene. 18 (29) Method of R. D. Haworth, J . Chem. SOC.,1125 (1932). (30) M. S . Newman, R. B. Taylor, H. Hodgson, and A. B. Garrett, J. Am. Chem. SOC.,69, 1784 (1947). (31) J. Szmuszkoviczand E. J. Modest, ibid., 72, 571 (1950). (32) J. Schmitt, R. Fallard, and M. Suguet, Bull. SOC.Chim. France, 1147 (1956), report the isolation of 3-(a-naphthyl)thiophcne from a mixture of products formed from the reaction of 2-naphthylbutene2 with S. These authors report mp 147" for their coapound in contrast to our liquid material (see above). Careful comparison of infrared spectra of our 3-(cr-naphthyl)thiophene with those of the other three ncphthylthiophene isomers prepared by us showed a good correlation of many characteristic peaks. The gas chromatographic retention time agreed well with that expected from the other isomers. Our structure is further confirmed by the fact that a material with spectral properties identical with those of our isomer is formed from the photolysis of 2-(cu-naphthyl)thiophene. Furthermore photolysis of 3-iodothiophene in naphthalene's gave a product with spectral properties identical with a mixture of our 3-(cu-naphthyl)- and 3-(P-naphthyl)thiophenes.

Wynberg, van Driel, Kellogg, Buter J Arylthiophene Rearrangements

3492 3-(P-Naphthyl)thiophene (12) was prepared with considerable difficulty from the Grignard reagent from 0-bromonaphthalene (obtained from the diazonium salt of P-naphthylamine).a3 The Grignard reagent from P-bromonaphthalene (21 g, 0.10 mole) was prepared in ether-benzene (4:1)34 and allowed t o react with 3ketotetrahydrothiophene (10.2 g, 0.10 mole). After work-up and distillation, the carbinol (15.5 g, 0.071 mole, 71 % yield), bp 175" (10 mm), obtained was immediately heated with KHSOl (1.75 g) and S (2.8 g) to 225" over 0.5 hr. Work-up and chromatography over A h 0 3 (petroleum ether-ether-methanol, 94 :3 :3) gave 340naphthy1)thiophene (10 g, 0.048 mole, 68% yield) as a dark solid. After repeated chromatography and recrystallization from petroleum ether, a pure sample was obtained, mp 145.5-146.5"; ultra301 (12,000), , , ,A 290 (14,700), violet spectrum in96Zethanol:, , A , , ,A 279 (12,900), , ,A 254 (37,200), and , , ,A 228 (39,600). Anal. Calcd for C14HlaS: C, 79.96; H, 4.79; S, 15.25. Found: C, 79.9; H,4.7; S, 15.2. 2,5-Diphenylthiophene (17) was obtained from a student collection and had been prepared35 from a modified procedure.36 Recrystallization from benzene-ethanol gave colorless plates, mp 153154" (lit.1P135153-154"); ultraviolet spectrum in 96% ethanol: ,,,A, 324 (28,400) and, , ,A 230 (11,900). A very strong fluorescence emission at 390 mp was observed, phosphorescence could not be detected. 3,4-Diphenylthiophene (15) was obtained from a sarnplea5prepared by decarboxylation of 3,4-diphenyl-2,5-dicarboxylthiophene. Recrystallization from benzene-methanol gave material, mp 113.5114", (lit.22335 114"); ultraviolet spectrum in 96% ethanol: , , ,A 234 (24,500) and Ash 260 (12,300). Medium intensity fluorescence at 342 mp was detected and also very strong phosphorescence a t 480 mp. 2,4-Diphenylthiophene (16) was prepared by heating styrene with sulfur in the presence of 2-mercaptobenzothiazole. 37 Redistilled styrene (40 g, 0.38 mole), sulfur (10 g, 0.3 g-atom), and 2-mercaptobenzothiazole (100 mg) were refluxed for 7 hr. The excess styrene was steam distilled in the presence of 10% NaOH; the undistilled residue was extracted with benzene and the benzene was dried and evaporated to leave a solid mass. The material was recrystallized twice out of benzene-methanol and chromatographed over AlzOa (benzene eluent). Addition of methanol to the benzene solution precipitated 2,4-diphenylthiophene (8.5 g, 0.036 mole, 19 % yield), mp 121.0-121.5" (lit.32z34 120.7-121.7"); ultraviolet spectrum in 96% ethanol: Am,,258(33,800), Ash 305 (9400), and Ash 224 (16,000). Strong fluorescence at 362 mp was detected and medium phosphorescence at 545 mp. 2,3-Diphenylthiophene (13) was obtained from a supply previously synthesized by reaction of the sodium salt of 3-phenyl-3-benzoylpropionic acid with phosphorus trisulfide. 35 This material was recrystallized from methanol and had mp 82.5-83' (lit.20 82.5-83"); 278 (11,400) and, , ,A ultraviolet spectrum in 96% ethanol: , , ,A 238 (20,300). Medium fluorescence at 390 mp was observed and weak phosphorescence at 560 mp. Synthesis of Phenanthro[9,10-b]thiophene (14).38 The synthesis of 9-phenanthrylthioglycolic acid was carried out using a modified combination of the methods of Wilputte and Martinlsa and that of Dutta. 151, 9-Bromophenanthrene was prepared by bromination of phenanthrene.39 The Grignard reagent was formed by reaction of the 9-bromophenanthrene (102 g, 0.4 mole) with magnesium (9.7 g, 0.4 g-atom) in a mixture of 150 ml of dry benzene and 100 ml of dry ether. The mixture was refluxed 1.5 hr; 100 ml of a 1 : l benzene-ether mixture was added, and the reaction mixture was allowed to reflux 40 hr. In small portions crystallized sulfur (14 g, 0.44 g-atom) was added, The reaction mixture became viscous during the addition and 300 ml of a 2 : 1 benzene-ether solution was added to overcome this. The reaction mixture was refluxed 5 hr, cooled, and hydrolyzed with 150 ml of 10% HCl and stored under

(33) M. S. Newman and P. H. Wise, J . Am. Chem. SOC.,63, 2847 (1941). (34) L. F. Fieser and E. B. Hershberg, ibid., 59, 1032 (1937). (35) J. L. Melles, Thesis, University of Groningen, Netherlands,

___

1957..

(36) S. Kapf and C. Paal, Ber., 21, 3053 (1880). (37) T. I